English

Improved second-order evaluation complexity for unconstrained nonlinear optimization using high-order regularized models

Optimization and Control 2021-05-31 v1 Computational Complexity

Abstract

The unconstrained minimization of a sufficiently smooth objective function f(x)f(x) is considered, for which derivatives up to order pp, p2p\geq 2, are assumed to be available. An adaptive regularization algorithm is proposed that uses Taylor models of the objective of order pp and that is guaranteed to find a first- and second-order critical point in at most O(max(ϵ1p+1p,ϵ2p+1p1))O \left(\max\left( \epsilon_1^{-\frac{p+1}{p}}, \epsilon_2^{-\frac{p+1}{p-1}} \right) \right) function and derivatives evaluations, where ϵ1\epsilon_1 and ϵ2>0\epsilon_2 >0 are prescribed first- and second-order optimality tolerances. Our approach extends the method in Birgin et al. (2016) to finding second-order critical points, and establishes the novel complexity bound for second-order criticality under identical problem assumptions as for first-order, namely, that the pp-th derivative tensor is Lipschitz continuous and that f(x)f(x) is bounded from below. The evaluation-complexity bound for second-order criticality improves on all such known existing results.

Keywords

Cite

@article{arxiv.1708.04044,
  title  = {Improved second-order evaluation complexity for unconstrained nonlinear optimization using high-order regularized models},
  author = {Coralia Cartis and Nicholas I. M. Gould and Philippe L. Toint},
  journal= {arXiv preprint arXiv:1708.04044},
  year   = {2021}
}
R2 v1 2026-06-22T21:13:49.099Z